一种用于实现无与伦比的水和有机物渗透的规则通道层状膜。

A Regularly Channeled Lamellar Membrane for Unparalleled Water and Organics Permeation.

作者信息

Wang Jingtao, Chen Pingping, Shi Benbing, Guo Weiwei, Jaroniec Mietek, Qiao Shi-Zhang

机构信息

School of Chemical Engineering and Energy, Zhengzhou University, Zhengzhou, 450001, China.

School of Chemical Engineering, University of Adelaide, Adelaide, SA, 5005, Australia.

出版信息

Angew Chem Int Ed Engl. 2018 Jun 4;57(23):6814-6818. doi: 10.1002/anie.201801094. Epub 2018 Mar 23.

DOI:10.1002/anie.201801094

PMID:29508511

Abstract

Lamellar membranes show exceptional molecular permeation properties of key importance for many applications. However, their design and development need the construction of regular and straight interlayer channels and the establishment of corresponding transport rate equation. The fabrication of a uniformly lamellar membrane is reported using double-layered Ti C T MXenes as rigid building blocks. This membrane possesses ordered and straight 2 nm channels formed via a direct self-stacking, in contrast to the conventional irregular ones from flexible sheets. Such channels permit precise molecular rejection and unparalleled molecular permeation. The permeance of water and organics by this membrane reached 2300 and 5000 L m h bar , respectively. The molecular transfer mechanism in confined nanochannels, and the corresponding model equation are established, paving a way to nanoscale design of highly efficient channeled membranes for transport and separation applications.

摘要

层状膜展现出了卓越的分子渗透特性，这对许多应用来说至关重要。然而，它们的设计与开发需要构建规则且笔直的层间通道，并建立相应的传输速率方程。据报道，使用双层Ti C T MXene作为刚性结构单元制备出了均匀的层状膜。与由柔性片材形成的传统不规则通道不同，这种膜具有通过直接自堆叠形成的有序且笔直的2纳米通道。此类通道允许精确的分子截留和无与伦比的分子渗透。该膜对水和有机物的渗透率分别达到了2300和5000 L m h bar。建立了受限纳米通道中的分子传输机制以及相应的模型方程，为用于传输和分离应用的高效通道膜的纳米级设计铺平了道路。

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一种用于实现无与伦比的水和有机物渗透的规则通道层状膜。

A Regularly Channeled Lamellar Membrane for Unparalleled Water and Organics Permeation.

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